System and Method for Improving Channel Efficiency in a Wireless Link

ABSTRACT

System and method for improving channel efficiency in a wireless link between an access-point transceiver and a first transceiver. The first transceiver may have a first data throughput rate that is lower than the maximum possible data throughput rate of the wireless link. The first transceiver may include a first receive buffer. An indication of the first data throughput rate and a size of the first receive buffer may be received and stored by the access-point transceiver. A first size of a first data packet for transmission to the first transceiver may be determined by the access-point transceiver based on one or more of the first data throughput rate and/or the size of the first receive buffer. The first data packet of the first size may be transmitted to the first transceiver by the access-point transceiver at a data rate that is higher than the first data throughput rate.

BACKGROUND

1. Field of the Disclosure

The present invention relates generally to wireless communication, andmore particularly to a system and method for improving channelefficiency in a wireless link between wireless devices.

2. Description of the Related Art

Wireless communication is being used for a plethora of applications,such as in laptops, cell phones, and other wireless communicationdevices (“wireless devices”). It has been common in the past for themaximum throughput rate of a wireless link to be the most limitingfactor in the speed of wireless communication. However, with theimprovement in wireless communication data rates and the increasinglywidespread implementation of wireless communication capabilities (e.g.,including in devices with relatively limited processing and/or interfacecapabililities), it is possible for a wireless device to be able tonatively support a lower maximum possible data throughput rate than themaximum possible data throughput rate of the wireless link. This canpotentially lead to problems.

As one example, a mobile device in an 802.11 (WLAN) network might insome situations (e.g., depending on the processing capability and/orwireless adapter interface of the mobile device and the quality of theWLAN link) not be able to process packets at as high of a rate as it ispossible for them to be transmitted over the WLAN link. In the absenceof any mitigating factors, this can lead to packet loss, extensive retryattempts, and rate drops, which in turn can cause power waste and maydegrade network capacity.

FIG. 1 illustrates two examples of how this could happen at twodifferent receivers, e.g., depending on the implementation. As shown,packets may be buffered initially, but eventually once the buffer isfull, packets may be dropped.

One simple solution is to limit the PHY rate of the wireless link to thehighest supported data rate of the limiting device. This would avoidunnecessary packet losses, but a given packet would take longer totransmit and receive than if the maximum PHY rate of the wireless linkwere used, resulting in higher power consumption and lower networkthroughput. Accordingly, improvements in the field would be desirable.

SUMMARY OF THE DISCLOSURE

Embodiments of the disclosure are presented in order to improve channelefficiency in a wireless link between two wireless devices. Morespecifically, embodiments of the disclosure are directed at situationsin which a data throughput rate of at least one of the two wirelessdevices wirelessly linked is lower than a maximum possible datathroughput rate of the wireless link itself.

Embodiments of the disclosure accordingly include methods for improvingchannel efficiency in a wireless link between an access-pointtransceiver (e.g., configured for use in an access-point wirelessdevice) and a first transceiver (e.g., configured for use in a firstwireless device), and systems configured to implement the methods. Insome embodiments, the wireless link may be an IEEE 802.11 wireless link,and the access-point transceiver and the first transceiver may becomprised in IEEE 802.11 enabled wireless devices. Alternate types ofwireless links are also considered.

The access-point transceiver may include an antenna for receiving andtransmitting wireless signals and a memory for storing parameterinformation for the wireless link. The access-point transceiver may alsoinclude control logic (which may include a processor and a memory mediumcomprising program instructions executable by the processor) coupled tothe antenna and the memory.

The first transceiver may include an antenna for receiving andtransmitting wireless signals. The first transceiver may also include areceive buffer. The first receive buffer may store information receivedby the first transceiver over the wireless link (e.g., via the antenna)for processing by the first transceiver. The first transceiver mayfurther include control logic (which may include a processor and amemory medium comprising program instructions executable by theprocessor) coupled to the antenna and/or the receive buffer, e.g., forprocessing data received via the wireless link. The first transceivermay have a first data throughput rate that is lower than the maximumdata throughput rate of the wireless link. In some embodiments, thefirst data throughput rate may be lower than the maximum possible datathroughput rate of the wireless link because of the data throughputcapability of one or more of a wireless link interface of the firsttransceiver and/or a processing capability of the first transceiver.

In a first set of embodiments, a system implementing a first method forimproving channel efficiency in the wireless link may include theaccess-point transceiver, or an access-point wireless device in whichthe access-point transceiver is implemented. In some embodiments, thecontrol logic of the access-point transceiver may be configured toimplement the method.

An indication of the first data throughput rate and a size of the firstreceive buffer may be received and stored. The indication of the firstdata throughput rate and the size of the first receive buffer may bedetermined by and received from the first transceiver via the antenna ofthe access-point transceiver.

A first size of a first data packet for transmission to the firsttransceiver may be determined. Determining the first size of the firstdata packet may be based on one or more of the first data throughputrate and/or the size of the first receive buffer. In one embodiment, thefirst size of the first data packet may be based on the size of thefirst receive buffer, and may be smaller than the size of the firstreceive buffer.

The first data packet of the first size may be transmitted to the firstreceiver. The first data packet may be transmitted via the antenna ofthe access-point transceiver. The first data packet of the first sizemay be transmitted to the first receiver at a data rate (e.g., asignaling or PHY rate) that is higher than the first data throughputrate.

In some embodiments, a first transmission frequency at which packets ofthe first size should be transmitted to the first transceiver may bedetermined. The first transmission frequency may be determined based onthe first data throughput rate. A plurality of data packets of the firstsize may thus be transmitted to the first transceiver at the firsttransmission frequency. Transmitting the plurality of data packets ofthe first size may be performed at a data rate (e.g., a signaling or PHYrate) that is higher than the first data throughput rate. In someembodiments, transmitting the plurality of data packets of the firstsize at the first transmission frequency at the data rate that is higherthan the first data throughput rate may provide data to the firsttransceiver at an effective data throughput rate that is at or below thefirst data throughput rate. In other words, transmitting the pluralityof data packets of the first size at the first transmission frequency atthe data rate that is higher than the first data throughput rate may notcause an overflow of the first receive buffer even though thetransmitting is occurring at a higher data rate than the first datathroughput rate.

Alternatively, in some embodiments, an available amount of memory in thefirst receive buffer may be estimated. Estimating the available amountof memory in the first receive buffer may be based on the first datathroughput rate, the size of the first receive buffer, the first size ofthe first data packet, and an elapsed time since transmission of thefirst data packet. A second size of a second data packet fortransmission to the first transceiver may be determined. The second sizeof the second data packet may be determined based on the estimatedavailable amount of memory in the first receive buffer. The second datapacket of the second size may be transmitted to the first transceiver ata data rate (e.g., a signaling or PHY rate) that is higher than thefirst data throughput rate.

In some embodiments, the wireless link may be extended to a secondtransceiver. It may be determined, based on the extension of thewireless link to the second transceiver, that the (effective) datathroughput to the first transceiver over the wireless link is unlikelyto exceed the first data throughput rate (although the actual signalingrate of transmissions may still be higher than the first data throughputrate). In this case, the access-point transceiver may not determinesizes of data packets for transmission to the first transceiver based onthe first data throughput rate or the size of the first receive buffer,e.g., in response to determining that data throughput to the firsttransceiver over the wireless link is unlikely to exceed the first datathroughput rate.

Alternatively, in some embodiments, the access-point transceiver mayperform traffic flow control for the second device as well. For example,the second transceiver (which may include a second receive buffer) mayhave a second data throughput rate that is lower than the maximumpossible data throughput rate of the wireless link. An indication of thesecond data throughput rate and a size of the second receive buffer maybe received and stored. A second size of a second data packet fortransmission to the second transceiver may be determined. Determiningthe second size of the second data packet may be based on one or more ofthe second data throughput rate and/or the size of the second receivebuffer. The second data packet of the second size may be transmitted tothe second transceiver at a data rate that is higher than the seconddata throughput rate.

In a second set of embodiments, a system implementing a second methodfor improving channel efficiency in the wireless link may include thefirst transceiver, or a first wireless device in which the firsttransceiver is implemented. In some embodiments, the control logic(e.g., a processor and a memory medium including program instructionsexecutable by the processor) of the first transceiver may be configuredto implement the method.

A first data frame may be received via the wireless link. The first dataframe may be stored in the receive buffer. An amount of available memoryin the receive buffer may be monitored and it may be determined that theamount of available memory in the receive buffer is below a firstthreshold.

A frame acknowledgement may be generated. The frame acknowledgement mayacknowledge receipt of the first data frame by the first transceiver.The frame acknowledgement may also include an indication of initiationof a power savings mode by the first transceiver. The indication ofinitiation of a power savings mode by the first transceiver may beincluded in the frame acknowledgement based on the determination thatthe amount of available memory in the receive buffer is below the firstthreshold. In some embodiments, the first transceiver may not actuallyenter a power savings mode, even though the first transceiver mayinclude the indication of initiation of a power savings mode by thefirst transceiver in the frame acknowledgement.

The frame acknowledgement may be transmitted to the access-pointtransceiver. The access-point transceiver may not transmit a next dataframe to the first transceiver after receiving the frame acknowledgementbased on the indication of initiation of the power savings mode.

The first data frame stored in the receive buffer may be processed(e.g., instead of entering a power savings mode). Based on processingthe first data frame in the receive buffer, the amount of availablememory in the receive buffer may increase above the second threshold. Itmay be determined (e.g., based on monitoring the amount of availablememory in the receive buffer) that the amount of available memory in thereceive buffer is above a second threshold.

An indication of termination of the power savings mode by the firsttransceiver may be generated. The indication of termination of the powersavings mode by the first transceiver may be transmitted to theaccess-point transceiver. Generating and transmitting the indication oftermination of the power savings mode by the first transceiver may bebased on the determination that the amount of available memory in thereceive buffer is above the second threshold. After receiving theindication of termination of the power savings mode by the firsttransceiver (e.g., and based on receiving the indication of terminationof the power savings mode by the first transceiver), the access-pointtransceiver may transmit the next data frame to the first transceiver.

BRIEF DESCRIPTION OF THE DRAWINGS

A better understanding of the present invention can be obtained when thefollowing Detailed Description of the Embodiments is read in conjunctionwith the following drawings, in which:

FIG. 1 is a diagram illustrating potential packet loss due tolimitations of a receiving device in a prior art system;

FIG. 2 illustrates exemplary wireless links between wireless devices,according to one embodiment;

FIGS. 3A and 3B are block diagrams of exemplary wireless devicesaccording to one embodiment;

FIGS. 4A and 4B are graph diagrams illustrating transmit and receivetiming and energy use at different wireless link PHY rates according toone embodiment; and

FIGS. 5-6 are flowchart diagrams illustrating embodiments of methods forimproving channel efficiency in a wireless link.

While the invention is susceptible to various modifications andalternative forms, specific embodiments thereof are shown by way ofexample in the drawings and are herein described in detail. It should beunderstood, however, that the drawings and detailed description theretoare not intended to limit the invention to the particular formdisclosed, but on the contrary, the intention is to cover allmodifications, equivalents and alternatives falling within the spiritand scope of the present invention as defined by the appended claims.

DETAILED DESCRIPTION OF EMBODIMENTS OF THE DISCLOSURE Terms

The following is a glossary of terms used in the present application:

Memory Medium—Any of various types of memory devices or storage devices.The terms “memory” and “memory medium” are intended to include aninstallation medium, e.g., a CD-ROM, floppy disks, or tape device; acomputer system memory or random access memory such as DRAM, DDR RAM,SRAM, EDO RAM, Rambus RAM, etc.; or a non-volatile memory such as flashmemory, hardware registers, a magnetic media (e.g., a hard drive), oroptical storage. The memory medium may comprise other types of memory aswell, or combinations thereof. The term “memory medium” may include twoor more memory mediums.

Computer System—Any of various types of mobile or stationary computingor processing systems, including a personal computer system (PC),mainframe computer system, workstation, network appliance, Internetappliance, mobile phone, smart phone, laptop, notebook, netbook, ortablet computer system, personal digital assistant (PDA), multimediadevice, or other device or combinations of devices. In general, the term“computer system” can be broadly defined to encompass any device (orcombination of devices) having at least one processor that executesinstructions from a memory medium.

Wireless Link—A wireless communicative coupling between two devices(which may be referred to as “wireless devices”). A wireless link may beestablished via any of a variety of wireless communication protocols,including any of various versions of IEEE 802.11 (WLAN), Bluetooth,Wibree, wireless USB, ZigBee, or any of various cellular networkprotocols, among others.

Access-Point Device—As used herein, an access-point device is considereda device that allows another device to establish a communicativecoupling (e.g., wireless and/or wired) with the access-point device.According to some communicative protocols, an access point device may berequired to be specifically configured to be an access point device,while other communicative protocols may allow any device configuredaccording to that protocol to act as an access-point device.

FIG. 2

Embodiments of the disclosure relate to improving channel efficiency inwireless links between wireless devices. FIG. 2 illustrates an exemplarysystem 200 including wireless links between wireless devices 202, 204,206, which may be configured to implement embodiments of thisdisclosure. The wireless links may enable wireless communication betweenwireless devices 202, 204, 206 according to any of a variety of wirelesscommunication technologies. In one exemplary implementation, thewireless links may be established as part of an IEEE 802.11 (WLAN)network. For example, wireless device 202 is shown as a router, and mayact as a gateway-type device (i.e., an access point transceiver). Thusin such an embodiment, any WLAN enabled wireless devices withincommunicative range, such as mobile phone 204 or laptop computer 206 (orboth), may establish a WLAN wireless link with router 202 to join theWLAN network.

In other envisioned embodiments, the wireless links may be establishedaccording to any of a variety of other wireless communication protocols.Examples of possible wireless technologies using which embodiments ofthe disclosure could be implemented include, without limitation,cellular networks, Bluetooth, ZigBee, Wireless USB, RFID, DedicatedShort Range Communications (DSRC), or any other suitable wirelesstechnology.

Furthermore, while the illustrated embodiment shows links specificallybetween router 202 and mobile phone 204, and router 202 and laptop 206,it should be noted that, in various embodiments, wireless links may bebetween any of a wide variety of suitable wireless devices, which mayinclude, without limitation, mobile phones (including smart phones);tablet, netbook, notebook, laptop, and/or desktop computers; personaldigital assistants; multimedia players (portable or stationary);routers, hubs, and/or other gateway type devices; and/or other mobiledevices/computing systems which are operable to use wirelesscommunication. In particular, it should be noted that while in someembodiments wireless links may need to be established through agateway-type device (such as router 202), other embodiments areenvisioned in which any wireless device may wirelessly communicatedirectly with any other wireless device (e.g., in which a wireless linkdirectly between mobile phone 204 and laptop computer 206 could beestablished).

In some embodiments, communication via a wireless link may be performedat a variety of possible data rates (“wireless link data throughputrates”). For example, in a WLAN wireless link, it may be possible forwireless signaling to be performed at a variety of different physical(PHY) layer data rates, up to a maximum supported data rate, which maydepend on what version of the protocol each device in the link supports,how many antennas each device utilizes (e.g., for Multiple InputMultiple Output (MIMO)), channel conditions, channel bandwidth, etc.

Independently of the wireless link data throughput rate, each of thewireless devices communicatively coupled by the wireless link may becapable of utilizing data received via the wireless link at a certainrate (a “wireless device data throughput rate”). This wireless devicedata throughput rate may be limited by one or more factors. For example,some wireless devices (e.g., devices which perform relatively limited orbasic functions) may have a relatively minimal native processingcapability. As another example, in some embodiments, a wireless linkinterface (e.g., a wireless adapter interface) could be a limitingfactor. A wireless device utilizing a wireless adapter which interfacesto the wireless device via USB, SDIO, or another interface, could belimited by the data throughput rate of that interface. Other limitationsare also possible.

If the wireless device data throughput rate of a wireless devicewirelessly linked to another wireless device is lower than the wirelesslink data throughput rate, it is possible that the wireless device willfall behind in processing the data received via the wireless link. Thiscan potentially result in extensive data loss and attempts to retransmitthe lost data, and/or a decreased wireless link data throughput rate.This, in turn, can degrade network capacity (e.g., in network-typewireless links), and cause significant power waste.

Accordingly, embodiments of the disclosure are directed to embodimentsof a method for improving channel efficiency in a wireless link betweenwireless devices in which at least one of the wireless devices has adata throughput rate that is lower than the maximum possible datathroughput rate of the wireless link. The method may provide receiveflow control for the limited wireless device in order that the maximumpossible data throughput rate of the wireless link may be used withoutthe extensive data loss and retry that might otherwise occur.

FIGS. 3A-3B

FIGS. 3A and 3B are simplified block diagrams illustrating variouscomponents of wireless devices which are capable of establishing awireless link with another wireless device according to variousembodiments of the disclosure.

FIG. 3A illustrates a wireless device 300 which includes a processor302, and a memory 304. The memory 304 may store program instructionsexecutable by the processor 302 to perform one or more aspects of themethods disclosed herein, and/or perform other device functionality. Thewireless device 300 may be any of a variety of types of device, and mayimplement any of a variety of functionalities, according to variousembodiments. For example, wireless device 300 may be a mobile phone(such as mobile phone 204 shown in FIG. 1) or smart phone, a laptop(such as laptop 206 shown in FIG. 2) or other computer, or generally anyother type of device which may be used to communicate wirelessly.

The wireless device 300 may also include a wireless adapter 306. Thewireless device 300 may utilize the wireless adapter 306 in order toform wireless links. According to some embodiments, the wireless adapter306 may be housed internally to (i.e., within a casing of) wirelessdevice 300, and may couple to an internal system bus or otherwise becommunicatively coupled to processor 302. Alternatively, wirelessadapter 306 may be coupled to wireless device 300 via an externalinterface (e.g., USB, SDIO, or any other external interface).

The wireless adapter 306 may implement one or more wireless protocols.In one example, wireless adapter 306 may be a WLAN adapter. In otherembodiments, wireless adapter 306 may implement other wirelessprotocols. Wireless adapter 306 may include circuitry configured toimplement the wireless protocol(s), including a receive buffer 308(e.g., to buffer received signals until they can be processed bywireless device 300) and an antenna 310 (e.g., to transmit and/orreceive signals wirelessly), among other possible components.Embodiments are also envisioned in which the wireless adapter 306includes multiple antennas (e.g., for MIMO and/or for implementingmultiple wireless protocols).

FIG. 3B illustrates a wireless device 350 including control logic 352, amemory 354, and an antenna 356. The wireless device 350 may be any of avariety of types of device, and may implement any of a variety offunctionalities, according to various embodiments. For example, wirelessdevice 350 may be a router (such as router 202 shown in FIG. 2), hub,gateway, or generally any type of device which may be used tocommunicate wirelessly.

According to some embodiments, the wireless device 350 may act as anaccess-point transceiver implementing one or more wireless protocols. Asone example, the wireless device 350 may be a WLAN router. In otherembodiments, wireless device 350 may be a different type of device. Thecontrol logic 352 may implement the wireless protocol(s), in combinationwith memory 354 (e.g., as a buffer and/or source of program instructionsfor a processor) and antenna 356 (e.g., to transmit and/or receivesignals wirelessly). Similar to wireless adapter 306 in wireless device300, the wireless device 350 may in some embodiments include multipleantennas (e.g., for MIMO and/or for implementing multiple wirelessprotocols).

As will be understood by those of skill in the art in light of thisdisclosure, wireless devices 300 and 350 may also include any of avariety of other components as desired, e.g., for implementing otherdevice functionality. Such components are not shown in order to avoidobscuring details of the disclosure.

In addition, it will be apparent that those components shown may beimplemented in any of a variety of ways, according to principles of themethods disclosed herein. For example, according to various embodiments,control logic 352 in wireless device 350 may be implemented using any ofvarious types of logic, such as analog logic, digital logic, a processorand memory (such as a CPU, DSP, microcontroller, etc.), an ASIC(application specific integrated circuit), an FPGA (field programmablegate array), or any combination of the above. Embodiments are similarlyenvisioned in which wireless device 300 utilizes other types of controllogic in addition to or instead of processor 302 and memory 304.

FIGS. 4A-4B

FIGS. 4A-4B illustrate transmit and receive timing and energy use of awireless device (e.g., any of wireless devices 202, 204, or 206 shown inFIG. 2) at different wireless link data rates (i.e., PHY or signalingrates). The illustrated examples may take place in a WLAN implementationaccording to one embodiment. FIGS. 4A-4B are intended to illustrate anequal amount of time elapsing and an equal amount of data beingtransmitted.

FIG. 4A illustrates a lower wireless link data rate relative to FIG. 4B.In both cases, the wireless device may transmit a frame (during whichtime full transmit power is used). Following this, the wireless devicemay enter an active search state, during which it may expect to receivea frame acknowledgement. During the search state, the receiver may bepartially powered. Once the receiver begins actively receiving the frameacknowledgement, the receiver may be fully powered. After the frameacknowledgement is received, the wireless device may wait for a periodof time (e.g., a random back-off (RBO)), before contending again forpermission to transmit data. During this time the receiver may bepartially powered (e.g., RX search automatic gain control (AGC) may beon) in case of incoming transmissions.

As shown, at the lower data rate of FIG. 4A, the active transmit periodof time may be longer than at the higher data rate of FIG. 4B.Accordingly, the energy used by the wireless device will be higher totransmit the same amount of data. Furthermore, a subtler point in WLANimplementations is that the transmit power at lower PHY rates maytypically be higher than the transmit power at higher PHY rates. Thismay be because error vector magnitude (EVM) requirements at the highestPHY rates may be more strict than at lower PHY rates, correspondinglyrequiring a lower transmit power. Thus, at a lower data rate, it may notonly take longer to transmit a given amount of data than at a higherdata rate, but more power may also be used per unit of time.

While the illustrated embodiments of FIGS. 4A-4B are directed to a WLANimplementation, it should be noted that similar (and/or other) concernsmay exist for other types of wireless links. Generally speaking, lowersignaling rates may be expected to take longer to transmit an equalamount of data, typically resulting in a higher power usage. It isdifficult to overstate the importance of power savings, especially inmobile devices in which battery life may be at a premium.

In addition to power usage related concerns, it is worth noting that thelarger amount of time required to transmit a given amount of data at alower signaling rate directly results in a degraded overall networkcapacity, e.g., in a network system (such as WLAN). In other words, if awireless device spends longer in transmitting and receiving data overthe network because it is forced to use a lower data rate, there maynecessarily be that much less time available to other wireless devicesin the network to communicate.

Accordingly, it is generally desirable to transmit at higher signalingrates when possible. However, as noted above with respect to FIG. 2,sometimes a receiving device has a data throughput rate that is lowerthan a maximum possible data throughput rate (e.g., signaling rate) of awireless link. In the absence of any mitigating factors, transmitting ata wireless link data throughput rate that is higher than a wirelessdevice data throughput rate may result in overflow of a receive bufferof the wireless device. Overflow of the receive buffer may in turn causedata transmitted over the wireless link to be lost. That lost data maybe retransmitted, sometimes repeatedly. Thus, power waste and networkcapacity may still be degraded. Furthermore, as a result of repeateddata loss at a higher wireless link data throughput rate, thecommunication protocol being used may require that a lower wireless linkdata throughput rate may be used, which, as noted above, also results inpower waste and degraded network capacity.

One possible solution, e.g., again in an exemplary WLAN implementation,would be to include a mechanism for flow control in a new version of theprotocol. For example, a field in block acknowledgement frames could bedefined to allow a wireless device which is receiving a frame to notifya wireless device which is transmitting the frame of how much receivebuffer remains available (e.g., in MAC protocol data units (MPDUs)).However, this mechanism may not be ideal. For example, this mechanismwould require new hardware support at both receiving and transmittingwireless devices. In addition, it would not be backward compatible andolder devices would not be able to take advantage of the mechanism.Furthermore, the mechanism would introduce additional complexity in bothreceiving and transmitting devices. For example, not only would thereceiving device need to be able to monitor/track its available buffersize, the transmitting device would need to be able to immediatelyadjust its transmit queue based on notifications of remaining availablebuffer of the receiving device. Two alternative mechanisms forcontrolling traffic flow, which have several advantages over thismethod, are provided below as the methods of FIGS. 5-6.

FIGS. 5-6

FIGS. 5-6 are flowchart diagrams illustrating embodiments of methods forimproving channel efficiency in a wireless link between a firsttransceiver (e.g., for use in a first wireless device) and anaccess-point transceiver (e.g., for use in an access-point wirelessdevice). According to some embodiments, the wireless link may be an IEEE802.11 (WLAN) wireless link, and the first and access-point transceiversmay be IEEE 802.11 enabled transceivers. The first wireless device maybe a mobile device in some embodiments; alternatively, the firstwireless device may be stationary.

Embodiments of the methods may be implemented by either of the first oraccess-point wireless devices. For example, the method of FIGS. 5A-5Bmay typically be implemented by the access-point wireless device whilethe method of FIGS. 6A-6B may typically be implemented by the firstwireless device. In some embodiments, the first and access-pointwireless devices implementing the method(s) may be implemented accordingto any of the systems of FIGS. 2-3 of this disclosure.

The methods may enable the wireless devices to communicate via thewireless link using a maximum supported data throughput rate (e.g., asignaling or PHY rate) of the wireless link even if one of the wirelessdevices (e.g., the first wireless device) has a data throughput rate(e.g., a device-limited maximum data throughput rate) that is lower thanthe maximum data throughput rate of the wireless link, withoutoverloading the limited wireless device and causing packet loss andextensive retry attempts. The methods may thereby result in improvedchannel efficiency in the wireless link relative to using a lower datathroughput rate of the wireless link or using the maximum supported datathroughput rate of the wireless link without the method.

The methods of FIGS. 5-6 may be used in combination (e.g., includingsome or all of the features of the methods of FIGS. 5-6) if desired.

While the steps described below with respect to FIGS. 5-6 are shown in acertain order, it should be noted that, according to variousembodiments, one or more of the steps may be omitted, repeated, orperformed in a different order than shown. One or more additional stepsmay also or alternatively be added, as desired.

As noted above, FIGS. 5A-5B illustrate a method for improving channelefficiency in a wireless link between a first transceiver and anaccess-point transceiver. In the method of FIGS. 5A-5B, the access-pointtransceiver may control the flow of transmissions to the firsttransceiver based on specific information regarding the capabilities ofthe first transceiver. In particular, the access-point transceiver maymake use of knowledge of a device-based data throughput rate of thefirst transceiver and a size of a receive buffer of the firsttransceiver in order to determine how frequently and/or how much data totransmit to the first transceiver. By controlling transmission flow,over-saturation of the receive buffer of the first transceiver (e.g., tothe point where data transmitted over the wireless link is lost) may beavoided. Thus, data may be transmitted to the first transceiver via thewireless link without the signaling rate over the wireless link beinglimited by the data throughput rate of the first transceiver.

The first transceiver may include an antenna for wirelessly transmittingand receiving signals via the wireless link. The first transceiver mayalso include a processor and memory for processing data received via thewireless link (and potentially for performing other functions). Thefirst transceiver may have a first data throughput rate that is lowerthan a data throughput rate of the wireless link. The first datathroughput rate may be lower than the wireless link data throughput linkbecause the first device may only capable of processing data (e.g., dueto processor or interface limitations, among other possible limitations)at the first data throughput rate or less. Alternatively, the firstdevice may not necessarily be limited to the first data throughput rate,but may currently be operating with the first data throughput rate(e.g., due to also performing other functions, or for any of a varietyof reasons).

The first transceiver may have a first receive buffer. The firsttransceiver may store data received (e.g., from the access-pointtransceiver) via the wireless link in the first receive buffer, forprocessing by the first transceiver. According to some embodiments, oncedata has been processed by the first transceiver, it may be removed fromthe first receive buffer.

The access-point transceiver may include an antenna for wirelesslytransmitting and receiving signals. The access-point transceiver mayfurther include a memory for storing parameter information for thewireless link, and potentially other information. Furthermore, theaccess point transceiver may include control logic coupled to theantenna and the memory. The control logic may be configured to implementthe method. The method may be performed as follows.

At step 502, an indication of the first data throughput rate and thesize of a first receive buffer of the first transceiver may be receivedand stored. In some embodiments, the first transceiver may determine thesize of the first receive buffer and/or the first data throughput rate.The first transceiver may accordingly transmit the indication of thefirst data throughput rate and the size of the first receive buffer tothe access point receiver.

Alternatively, embodiments are considered in which the access-pointtransceiver may receive the indication of the first data throughput rateand the size of the first receive buffer in another manner. For example,the access point transceiver could query a database correlating types ofwireless devices with receive buffer sizes and data throughput ratesbased on a type/model of device of the first wireless device. Thedatabase might be locally stored/maintained (e.g., by the access-pointtransceiver) or remotely stored/maintained (e.g., by another device towhich the access-point transceiver has communicative access), amongother possible options.

At step 504, a first size of a first data packet for transmission to thefirst transceiver may be determined. The first size of the first datapacket may be determined based on the first data throughput rate and/orthe size of the first receive buffer. In some embodiments, the firstsize of the first data packet may be based only on the size of the firstreceive buffer; for example, the first size of the first data packet maybe smaller than the first receive buffer. In some embodiments, the firstsize of the first data packet may be determined such that an integernumber of packets may fit in the first receive buffer, although in otherembodiments this may not be a consideration.

At step 506, the first data packet of the first size may be transmittedto the first transceiver. The first data packet of the first size may betransmitted to the first transceiver at a signaling rate (a datathroughput rate of the wireless link) that is higher than the first datathroughput rate.

In some embodiments, a first transmission frequency at which packets ofthe first size should be transmitted to the first transceiver may alsobe determined. In this case, a plurality of data packets of the firstsize may be transmitted to the first transceiver at the firsttransmission frequency. The first transmission frequency may be based(at least in part) on a wireless link data throughput rate (e.g., asignaling or PHY rate) of the wireless link.

The frequency with which packets of the first size should be transmittedto the first transceiver may be determined based on the first datathroughput rate. The first size of data packets and the determinedfrequency may be configured to avoid overflowing the first receivebuffer. The first size of data packets and the determined frequency mayin some embodiments more specifically be configured to provide data tothe first transceiver substantially at the first data throughput rate.In other words, the access-point transceiver may transmit data packetsat a signaling rate that is higher than the first data throughput rate,but may transmit data packets frequently enough (e.g., less frequentlythan is possible) to match the first data throughput rate of the firsttransceiver.

FIG. 5B illustrates an optional extension of the method of FIG. 5A. Forexample, as an alternative to simply determining a first frequency atwhich to transmit the first sized packets to the first transceiver, theaccess-point transceiver may utilize the information available to it toestimate an available amount of memory in the first receive buffer, andbase transmissions (e.g., size of packets and/or timing oftransmissions) on such estimates. As with the method of FIG. 5A, themethod may be implemented by control logic of the access-pointtransceiver. The method may be performed as follows.

At step 508, an available amount of memory in the first receive buffermay be estimated. The available amount of memory in the first receivebuffer may be estimated based on the first data throughput rate, thesize of the first receive buffer, the first size of the first datapacket, and an elapsed time since transmission of the first data packet.For example, the available amount of memory in the first receive buffermight be estimated according to the formula:

EST=BUFF−(PACK−(THRU*TIME))

where EST is the estimated available amount of memory, BUFF is the sizeof the first receive buffer, PACK is the first size of the first datapacket, THRU is the first data throughput rate, and TIME is the elapsedtime since transmission of the first data packet. It should be notedthat this formula is intended to be exemplary and non-limiting; othermethods of estimating the available amount of memory in the firstreceive buffer are also envisioned.

At step 510, a second size of a second data packet for transmission tothe first transceiver may be determined. The second size of the seconddata packet may be determined based on the estimated available amount ofmemory in the first receive buffer. The second size of the second datapacket may be smaller than the available amount of memory in the firstreceive buffer, e.g., in order that transmission of the second packet ofthe second size to the first transceiver does not overflow the firstreceive buffer. The second size may be different than the first size,although it is also possible that the second size may the same as thefirst size.

Alternatively, or an addition, in some embodiments the access-pointtransceiver may also use the estimated available amount of memory in thefirst receive buffer to determine timing of transmission of the seconddata packet for transmission to the first transceiver. For example, ifit is determined that the estimated available amount of memory in thefirst receive buffer is so small that constructing a packet sufficientlysmall to be completely buffered in the available amount of memory in thefirst receive buffer would be relatively inefficient, the access-pointtransceiver may wait a predetermined or dynamic amount of time (e.g.,based on knowledge of the first data throughput rate and the estimatedavailable amount of memory in the first receive buffer) beforere-assessing the available amount of memory in the first receive bufferand determining the second size of the second data packet.

At step 512, the second data packet of the second size may betransmitted to the first transceiver. As with the first data packet ofthe first size, the second data packet of the second size may betransmitted at a signaling rate (a data throughput rate of the wirelesslink) that is higher than the first data throughput rate.

It should be noted that in some embodiments, the access-pointtransceiver may be capable of extending a wireless link to a secondtransceiver (e.g., in another wireless device) at the same time as thewireless link with the first transceiver is active. For example, in aWLAN implementation, the access-point wireless device may be configuredto form wireless links with a plurality of wireless devices to form awireless network.

If the second transceiver has a second receive buffer and a second datathroughput rate which is also lower than the data throughput rate of thewireless link, the access-point transceiver may be configured to performone or more aspects of the method, as described with respect to thefirst transceiver, with respect to the second transceiver.

For example, the access-point transceiver may, in this case, beconfigured to receive and store an indication of the second datathroughput rate and the size of the second receive buffer. A second sizeof a second data packet for transmission to the second transceiver maybe determined based on one or more of the second data throughput rateand/or the size of the second receive buffer. The second data packet ofthe second size may be transmitted to the second transceiver at a datarate that is higher than the second data throughput rate.

Other aspects of the method may also be performed with respect to thesecond transceiver. Alternatively, in some embodiments extension of thewireless link to a second transceiver may decrease the effective datathroughput over the wireless link to each of the first and secondtransceivers to a point at which neither the first data throughput ratenor the second data throughput rate is likely to be exceeded. It shouldbe noted that in this case, the signaling rate over the wireless link toeach of the first and second transceivers may still be higher than thefirst and/or second data throughput rates, but because transmissions maysometimes alternate, between the access-point transceiver and the firsttransceiver, and between the access-point transceiver and the secondtransceiver, neither the first receive buffer nor the second receivebuffer may experience overflow.

The access-point transceiver may, in this case, determine that datathroughput to the first transceiver over the wireless link is unlikelyto exceed the first data throughput rate (e.g., based on the extensionof the wireless link to the second transceiver). In response to this,the access-point transceiver may not determine sizes of data packets fortransmission to the first transceiver based on the first data throughputrate or the size of the first receive buffer. In other words, theaccess-point transceiver may no longer perform flow control for thefirst wireless device if it determines that it is no longer necessary todo so.

Thus, according to the method of FIGS. 5A-5B, the access-pointtransceiver may control flow of transmissions from the access-pointtransceiver to the first transceiver in such a way that the firsttransceiver may receive data packets at a signaling rate which is higherthan the data throughput rate of the first transceiver, withoutundergoing receive buffer overflow, resulting packet loss, andcorresponding transmission retry attempts.

One advantage of the method is that since the method may be implementedby the access-point transceiver, even an older device implemented as thefirst transceiver may be capable of taking advantage of the method.Depending on the embodiment, such an older first transceiver may or maynot require a driver update (e.g., in order to be configured todetermine and transmit an indication of its receive buffer size andfirst data throughput rate). This may be especially useful as olderdevices may more commonly have device-based limitations to datathroughput (e.g., due to older processors or wireless link interfaces).

Similar to FIGS. 5A-5B, which are described above, FIGS. 6A-6Billustrate a method for improving channel efficiency in a wireless linkbetween a first transceiver and an access-point transceiver. In contrastto the method of FIGS. 5A-5B, the method of FIGS. 6A-6B may be performedby the first transceiver, and may operate by leveraging a power savingsmode to perform receive flow control on transmissions received from theaccess-point transceiver.

At step 602, a first data frame may be received via a wireless link(e.g., via the antenna of the first transceiver). The first data framemay be received from the access-point transceiver.

At step 604, the first data frame may be stored in a receive buffer.

At step 606, it may be determined that an amount of available memory inthe receive buffer is below a first threshold. The amount of availablememory in the receive buffer may fall below the first threshold in partas a result of the first data frame being stored in the receive buffer.The amount of available memory in the receive buffer may fall below thefirst threshold additionally in part because the first transceiver isunable to process data received via the wireless link as fast as data isreceived via the wireless link. For example, a data throughput rate ofthe first transceiver may be lower than a data throughput rate (e.g., asignaling rate) of the wireless link, e.g., because of processorlimitations, wireless link interface limitations, and/or otherlimitations of the first transceiver.

In some embodiments, the first threshold may be configured such thatthere is substantially no available memory in the receive buffer whenthe amount of available memory in the receive buffer falls below thefirst threshold. Alternatively, the first threshold may be configuredsuch that some small or moderate amount of available memory in thereceive buffer remains when the amount of available memory in thereceive buffer falls below the first threshold, e.g., in order tomaintain sufficient buffer for any subsequently received data before theframe acknowledgement (described subsequently with respect to steps 608and 610) is received by the access-point transceiver. Any of a varietyof other values for the first threshold are also considered.

At step 608, a frame acknowledgement may be generated. The frameacknowledgement may acknowledge receipt of the first data frame. Theframe acknowledgement may also indicate initiation of a power savingsmode, based on determining that the amount of available memory in thereceive buffer is below the first threshold.

At step 610, the frame acknowledgement may be transmitted to theaccess-point transceiver. The access-point transceiver may not transmita next data frame to the first transceiver after receiving the frameacknowledgement, based on the indication of initiation of the powersavings mode. For example, the access-point transceiver may determine,based on the indication of initiation of the power savings mode, thatthe first transceiver is currently in a power savings mode and notcapable of receiving transmissions.

It should be noted that the first transceiver may be capable, as part ofa wireless communication protocol according to which the wireless linkis formed, of entering a power savings mode in which the firsttransceiver neither transmits nor receives data wirelessly, and in whichthe first transceiver does not process data. As one example, a powersavings mechanism exists in the 802.11 protocol. Other power savingsmechanisms are also known. It should be noted that in some embodimentsof the method, despite indicating in the frame acknowledgement thatinitiation of the power savings mode has occurred, the first transceivermay not actually enter the power savings mode. In other words, the firsttransceiver may indicate that initiation of the power savings mode hasoccurred but may remain active in processing data received via thewireless link, e.g., in order to free up space in the first receivebuffer. For example, in some embodiments, the method may continue asshown in FIG. 6B and described below with respect thereto.

At step 612, the first data frame in the receive buffer may beprocessed. According to some embodiments, the first transceiver mayinclude a processor or other logic configured to process the first dataframe in the receive buffer.

At step 614, it may be determined that the amount of available memory inthe receive buffer is above a second threshold. The amount of availablememory in the receive buffer may increase above the second thresholdbased on the processing of the first data frame in the receive buffer.The second threshold may have any of a variety of values and may beconfigured in any of a variety of ways. As one example, the secondthreshold may be configured such that the amount of available memory inthe receive buffer is sufficient to buffer at least one additional dataframe. In some embodiments, the second threshold may be determined suchthat substantially all of the memory in the receive buffer is availablebefore the amount of available memory in the receive buffer is above thesecond threshold. However, in some embodiments, it may be desirable thatthere be some received data remaining in the receive buffer for thefirst transceiver to process when the amount of available memory in thereceive buffer rises above the second threshold, e.g., in order that agap in processing of received data may be avoided.

At step 616, an indication of termination of the power savings mode bythe first transceiver may be generated, based on determining that theamount of available memory in the receive buffer is above the secondthreshold. The indication of termination of the power savings mode maybe configured for transmission to the access-point transceiver. Forexample, the indication of termination of the power savings mode may beconfigured to indicate to the access-point transceiver that the firsttransceiver is ready to receive data via the wireless link.

At step 618, the indication of termination of the power savings mode bythe first transceiver may be transmitted to the access-pointtransceiver. The access-point transceiver may transmit the next dataframe to the first transceiver after receiving the indication oftermination of the power savings mode by the first transceiver. In someembodiments, the next data frame may be transmitted to the firsttransceiver via the wireless link at a higher data rate (e.g., signalingrate) than the data throughput rate of the first transceiver.

Thus, according to the method of FIGS. 6A-6B, the first transceiver mayleverage an existing power savings mechanism to control receive flow oftransmissions from the access-point transceiver. As a result, the firsttransceiver may receive data frames at a signaling rate which is higherthan the data throughput rate of the first transceiver withoutundergoing receive buffer overflow, resulting packet loss, andcorresponding transmission retry attempts.

The method of FIGS. 6A-6B may be advantageous insofar as the data flowto the first transceiver may be controlled by the first transceiver, andno updates may be necessary at the access-point transceiver. However,because the method may require a hardware update to implement the methodin the first transceiver, legacy devices may not be capable of takingadvantage of the method.

One possible concern with the method is that if the power savings modeinitiation and termination indications are exchanged overly frequently,the overhead incurred could negatively affect communications via thewireless link. However, if the receive buffer is relatively largecompared to an average frame size, this exchange may occur relativelyinfrequently.

Exemplary Table

Table 1 provided below compares the impact on receive duration andchannel efficiency if a wireless link between two devices has to belimited by PHY rate or to be only limited by receive buffer size in anon-limiting exemplary WLAN implementation. In the exemplaryimplementation of Table 1, it is assumed that the devices support 256QAMmodulation, with 80 MHz channels, single chain communication, MSDU sizeof 1500B (no AMSDU), and maximum AMPDU size of 32 MPDU/MSDU. Thus thehighest supported PHY rate (wireless link data throughput rate) is 433Mbps. It is further assumed that device is hardware-limited to a devicedata throughput rate of 250 Mbps.

TABLE 1 Limit by Limit Limit Limit PHY rate AMPDU AMPDU AMPDU (234 sizesize size Mbps) by 64 KB by 32 KB by 16 KB PSDU size/Aggr size 49.2 KB/49.2 KB/ 30.8 KB/20 15 KB/10 32 32 PSDU length 1.73 ms 0.95 ms 0.6 ms0.32 ms Channel efficiency 46.2% 78.3% 70.7% 56%

The first case (limit by PHY rate) is a situation in which the PHY rateof the wireless link is dropped down to a level (234 Mbps) supported bythe receiving wireless device. The other three cases (limit AMPDU size)illustrate situations in which the maximum supported PHY rate (433 Mbps)is used for the wireless link, but traffic flow control (e.g., accordingto either of the methods of FIGS. 5-6) is used to improve channelefficiency. In these three cases, the size of the receive buffer doesaffect the channel efficiency, but as shown, channel efficiency issignificantly improved over the PHY rate limited case even when receivebuffer size is smaller than in the exemplary PHY rate limited case.

Although the embodiments above have been described in considerabledetail, numerous variations and modifications will become apparent tothose skilled in the art once the above disclosure is fully appreciated.It is intended that the following claims be interpreted to embrace allsuch variations and modifications.

1. A method for improving channel efficiency in a wireless link betweenan access-point transceiver and a first transceiver, wherein the firsttransceiver has a first data throughput rate that is lower than themaximum possible data throughput rate of the wireless link, wherein thefirst transceiver comprises a first receive buffer, the methodcomprising: receiving and storing, by the access-point transceiver, anindication of the first data throughput rate and a size of the firstreceive buffer; determining, by the access-point transceiver, a firstsize of a first data packet for transmission to the first transceiver,wherein said determining is based on one or more of: 1) the first datathroughput rate; and/or 2) the size of the first receive buffer;transmitting, by the access-point transceiver, the first data packet ofthe first size to the first transceiver at a data rate that is higherthan the first data throughput rate.
 2. The method of claim 1, furthercomprising: determining, by the access-point transceiver, a firsttransmission frequency at which packets of the first size should betransmitted to the first transceiver based on the first data throughputrate; transmitting a plurality of data packets of the first size to thefirst transceiver at the first transmission frequency, wherein saidtransmitting is performed at a data rate that is higher than the firstdata throughput rate.
 3. The method of claim 1, further comprising:estimating, by the access-point transceiver, an available amount ofmemory in the first receive buffer, wherein said estimating is based onthe first data throughput rate, the size of the first receive buffer,the first size of the first data packet, and an elapsed time sincetransmission of the first data packet; determining, by the access-pointtransceiver, a second size of a second data packet for transmission tothe first transceiver based on the estimated available amount of memoryin the first receive buffer; transmitting, by the access-pointtransceiver, the second data packet of the second size to the firsttransceiver at a data rate that is higher than the first data throughputrate.
 4. The method of claim 1, wherein the first data throughput rateis determined by the first transceiver; wherein the indication of thefirst data throughput rate and the size of the receive buffer arereceived by the access-point transceiver from the first transceiver. 5.The method of claim 1, wherein the first data throughput rate is lowerthan the maximum possible data throughput rate of the wireless linkbecause of the data throughput capability of one or more of: 1) awireless link interface of the first transceiver; and/or 2) a processingcapability of the first transceiver.
 6. The method of claim 1, furthercomprising: extending, by the access-point transceiver, the wirelesslink to a second transceiver, wherein the second transceiver has asecond data throughput rate that is lower than the maximum possible datathroughput rate of the wireless link, wherein the second transceivercomprises a second receive buffer: receiving and storing, by theaccess-point transceiver, an indication of the second data throughputrate and a size of the second receive buffer; determining, by theaccess-point transceiver, a second size of a second data packet fortransmission to the second transceiver, wherein said determining isbased on one or more of: 1) the second data throughput rate; and/or 2)the size of the second receive buffer; transmitting, by the access-pointtransceiver, the second data packet of the second size to the secondtransceiver at a data rate that is higher than the second datathroughput rate.
 7. The method of claim 1, further comprising:extending, by the access-point transceiver, the wireless link to asecond transceiver; determining, by the access-point transceiver, thatdata throughput to the first transceiver over the wireless link isunlikely to exceed the first data throughput rate based on the extensionof the wireless link to the second transceiver; wherein the access-pointtransceiver does not determine sizes of data packets for transmission tothe first transceiver based on the first data throughput rate or thesize of the first receive buffer in response to determining that datathroughput to the first transceiver over the wireless link is unlikelyto exceed the first data throughput rate.
 8. The method of claim 1,wherein the first size of the first data packet is smaller than the sizeof the first receive buffer.
 9. The method of claim 1, wherein the firstreceive buffer stores information received by the first transceiver overthe wireless link for processing by the first transceiver.
 10. Themethod of claim 1, wherein the wireless link is an 802.11 wireless link.11. A access-point transceiver configured to improve channel efficiencyin a wireless link with a first transceiver, wherein the firsttransceiver has a first data throughput rate that is lower than themaximum possible data throughput rate of the wireless link, wherein thefirst transceiver comprises a first receive buffer, the access-pointtransceiver comprising: an antenna for receiving and transmittingwireless signals; a memory for storing parameter information for thewireless link; control logic coupled to the antenna and the memory,wherein the control logic is configured to: receive an indication of thefirst data throughput rate and a size of the first receive buffer; storeinformation indicating the first data throughput rate and the size ofthe first receive buffer in the memory; determine a first size of afirst data packet for transmission to the first transceiver based on oneor more of: 1) the first data throughput rate; and/or 2) the size of thefirst receive buffer; transmit, via the antenna, the first data packetof the first size to the first transceiver at a data rate that is higherthan the first data throughput rate.
 12. The access-point transceiver ofclaim 11, wherein the control logic is further configured to: determinea first transmission frequency at which packets of the first size shouldbe transmitted to the first transceiver based on the first datathroughput rate; transmit, via the antenna, a plurality of data packetsof the first size to the first transceiver at the first transmissionfrequency, wherein said transmitting is at a data rate that is higherthan the first data throughput rate.
 13. The access-point transceiver ofclaim 11, wherein the control logic is further configured to: estimatean available amount of memory in the first receive buffer based on thefirst data throughput rate, the size of the first receive buffer, thefirst size of the first data packet, and an elapsed time sincetransmission of the first data packet; determine a second size of asecond data packet for transmission to the first transceiver based onthe estimated available amount of memory in the first receive buffer;transmit, via the antenna, the second data packet of the second size tothe first transceiver at a data rate that is higher than the first datathroughput rate.
 14. The access-point transceiver of claim 11, whereinthe first data throughput rate is lower than the maximum possible datathroughput rate of the wireless link because of the data throughputcapability of one or more of: 1) a wireless link interface of the firsttransceiver; and/or 2) a processing capability of the first transceiver.15. The access-point transceiver of claim 11, wherein the control logicis further configured to: extend the wireless link to a secondtransceiver, wherein the second transceiver has a second data throughputrate that is lower than the maximum possible data throughput rate of thewireless link, wherein the second transceiver comprises a second receivebuffer; receive an indication of the second data throughput rate and asize of the second receive buffer; store information indicating thesecond data throughput rate and the size of the second receive buffer inthe memory; determine a second size of a second data packet fortransmission to the second transceiver based on one or more of: 1) thesecond data throughput rate; and/or 2) the size of the second receivebuffer; transmit, via the antenna, the second data packet of the secondsize to the second transceiver at a data rate that is higher than thesecond data throughput rate.
 16. The access-point transceiver of claim11, wherein the control logic is further configured to: extend thewireless link to a second transceiver; determine that data throughput tothe first transceiver over the wireless link is unlikely to exceed thefirst data throughput rate based on the extension of the wireless linkto the second transceiver; wherein the access-point transceiver isconfigured to not determine sizes of data packets for transmission tothe first transceiver based on the first data throughput rate or thesize of the first receive buffer in response to determining that datathroughput to the first transceiver over the wireless link is unlikelyto exceed the first data throughput rate.
 17. The access-pointtransceiver of claim 11, wherein the first size of the first data packetis smaller than the size of the first receive buffer.
 18. Theaccess-point transceiver of claim 11, wherein the first receive bufferstores information received by the first transceiver over the wirelesslink for processing by the first transceiver.
 19. The access-pointtransceiver of claim 11, wherein the control logic is configured toreceive the indication of the first data throughput rate and the size ofthe first receive buffer, via the antenna, from the first transceiver.20. The access-point transceiver of claim 11, wherein the wireless linkis an 802.11 wireless link, wherein the access-point transceiver is an802.11 access-point transceiver.
 21. A method for use by a firsttransceiver to improve channel efficiency in a wireless link with anaccess-point transceiver, wherein the first transceiver comprises afirst receive buffer, the method comprising: receiving a first dataframe from the access-point transceiver via the wireless link; storingthe first data frame in the receive buffer; determining that an amountof available memory in the receive buffer is below a first threshold;generating a frame acknowledgement, wherein the frame acknowledgmentacknowledges receipt of the first data frame by the first transceiver,wherein the frame acknowledgement further comprises an indication ofinitiation of a power savings mode by the first transceiver based on thedetermination that the amount of available memory in the receive bufferis below the first threshold; transmitting the frame acknowledgement tothe access-point transceiver; wherein the access-point transceiver doesnot transmit a next data frame to the first transceiver after receivingthe frame acknowledgement based on the indication of initiation of thepower savings mode.
 22. The method of claim 21, further comprising:processing the first data frame in the receive buffer; determining thatthe amount of available memory in the receive buffer is above a secondthreshold; generating an indication of termination of the power savingsmode by the first transceiver based on the determination that the amountof available memory in the receive buffer is above the second threshold;transmitting the indication of termination of the power savings mode bythe first transceiver to the access-point transceiver; wherein theaccess-point transceiver transmits the next data frame to the firsttransceiver after receiving the indication of termination of the powersavings mode by the first transceiver;
 23. The method of claim 22,wherein the amount of available memory in the receive buffer increasesabove the second threshold based on said processing the first data framein the receive buffer.